/* --------------------------------------------------------------------------
 * gin_private.h
 *	  header file for openGauss inverted index access method implementation.
 *
 *	Copyright (c) 2006-2014, PostgreSQL Global Development Group
 *
 *	src/include/access/gin_private.h
 * --------------------------------------------------------------------------
 */
#ifndef GIN_PRIVATE_H
#define GIN_PRIVATE_H

#include "access/genam.h"
#include "access/gin.h"
#include "access/itup.h"
#include "fmgr.h"
#include "storage/buf/bufmgr.h"
#include "utils/rbtree.h"

/*
 * Page opaque data in an inverted index page.
 *
 * Note: GIN does not include a page ID word as do the other index types.
 * This is OK because the opaque data is only 8 bytes and so can be reliably
 * distinguished by size.  Revisit this if the size ever increases.
 * Further note: as of 9.2, SP-GiST also uses 8-byte special space.  This is
 * still OK, as long as GIN isn't using all of the high-order bits in its
 * flags word, because that way the flags word cannot match the page ID used
 * by SP-GiST.
 */
typedef struct GinPageOpaqueData {
    BlockNumber rightlink; /* next page if any */
    OffsetNumber maxoff;   /* number of PostingItems on GIN_DATA &
                            * ~GIN_LEAF page. On GIN_LIST page, number of
                            * heap tuples. */
    uint16 flags;          /* see bit definitions below */
} GinPageOpaqueData;

typedef GinPageOpaqueData *GinPageOpaque;

#define GIN_DATA (1 << 0)
#define GIN_LEAF (1 << 1)
#define GIN_DELETED (1 << 2)
#define GIN_META (1 << 3)
#define GIN_LIST (1 << 4)
#define GIN_LIST_FULLROW (1 << 5) /* makes sense only on GIN_LIST page */
#define GIN_INCOMPLETE_SPLIT                   \
    (1 << 6) /* page was split, but parent not \
              * updated */
#define GIN_COMPRESSED (1 << 7)

/* Page numbers of fixed-location pages */
#define GIN_METAPAGE_BLKNO (0)
#define GIN_ROOT_BLKNO (1)

typedef struct GinMetaPageData {
    /*
     * Pointers to head and tail of pending list, which consists of GIN_LIST
     * pages.  These store fast-inserted entries that haven't yet been moved
     * into the regular GIN structure.
     */
    BlockNumber head;
    BlockNumber tail;

    /*
     * Free space in bytes in the pending list's tail page.
     */
    uint32 tailFreeSize;

    /*
     * We store both number of pages and number of heap tuples that are in the
     * pending list.
     */
    BlockNumber nPendingPages;
    int64 nPendingHeapTuples;

    /*
     * Statistics for planner use (accurate as of last VACUUM)
     */
    BlockNumber nTotalPages;
    BlockNumber nEntryPages;
    BlockNumber nDataPages;
    int64 nEntries;

    /*
     * GIN version number (ideally this should have been at the front, but too
     * late now.  Don't move it!)
     *
     * Currently 2 (for indexes initialized in 9.4 or later)
     *
     * Version 1 (indexes initialized in version 9.1, 9.2 or 9.3), is
     * compatible, but may contain uncompressed posting tree (leaf) pages and
     * posting lists. They will be converted to compressed format when
     * modified.
     *
     * Version 0 (indexes initialized in 9.0 or before) is compatible but may
     * be missing null entries, including both null keys and placeholders.
     * Reject full-index-scan attempts on such indexes.
     */
    int32 ginVersion;
} GinMetaPageData;

#define GIN_CURRENT_VERSION 2

#define GinPageGetMeta(p) ((GinMetaPageData *)PageGetContents(p))

/*
 * Macros for accessing a GIN index page's opaque data
 */
#define GinPageGetOpaque(page) ((GinPageOpaque)PageGetSpecialPointer(page))

#define GinPageIsLeaf(page) (GinPageGetOpaque(page)->flags & GIN_LEAF)
#define GinPageSetLeaf(page) (GinPageGetOpaque(page)->flags |= GIN_LEAF)
#define GinPageSetNonLeaf(page) (GinPageGetOpaque(page)->flags &= ~GIN_LEAF)
#define GinPageIsData(page) (GinPageGetOpaque(page)->flags & GIN_DATA)
#define GinPageSetData(page) (GinPageGetOpaque(page)->flags |= GIN_DATA)
#define GinPageIsList(page) (GinPageGetOpaque(page)->flags & GIN_LIST)
#define GinPageSetList(page) (GinPageGetOpaque(page)->flags |= GIN_LIST)
#define GinPageHasFullRow(page) (GinPageGetOpaque(page)->flags & GIN_LIST_FULLROW)
#define GinPageSetFullRow(page) (GinPageGetOpaque(page)->flags |= GIN_LIST_FULLROW)
#define GinPageIsCompressed(page) (GinPageGetOpaque(page)->flags & GIN_COMPRESSED)
#define GinPageSetCompressed(page) (GinPageGetOpaque(page)->flags |= GIN_COMPRESSED)

#define GinPageIsDeleted(page) (GinPageGetOpaque(page)->flags & GIN_DELETED)
#define GinPageSetDeleted(page) (GinPageGetOpaque(page)->flags |= GIN_DELETED)
#define GinPageSetNonDeleted(page) (GinPageGetOpaque(page)->flags &= ~GIN_DELETED)
#define GinPageIsIncompleteSplit(page) (GinPageGetOpaque(page)->flags & GIN_INCOMPLETE_SPLIT)

#define GinPageRightMost(page) (GinPageGetOpaque(page)->rightlink == InvalidBlockNumber)

/*
 * We use our own ItemPointerGet(BlockNumber|OffsetNumber)
 * to avoid Asserts, since sometimes the ip_posid isn't "valid"
 */
#define GinItemPointerGetBlockNumber(pointer) BlockIdGetBlockNumber(&(pointer)->ip_blkid)

#define GinItemPointerGetOffsetNumber(pointer) ((pointer)->ip_posid)

/*
 * Special-case item pointer values needed by the GIN search logic.
 *	MIN: sorts less than any valid item pointer
 *	MAX: sorts greater than any valid item pointer
 *	LOSSY PAGE: indicates a whole heap page, sorts after normal item
 *				pointers for that page
 * Note that these are all distinguishable from an "invalid" item pointer
 * (which is InvalidBlockNumber/0) as well as from all normal item
 * pointers (which have item numbers in the range 1..MaxHeapTuplesPerPage).
 */
#define ItemPointerSetMin(p) ItemPointerZero(p)
#define ItemPointerIsMin(p) \
    (GinItemPointerGetOffsetNumber(p) == (OffsetNumber)0 && GinItemPointerGetBlockNumber(p) == (BlockNumber)0)
#define ItemPointerSetMax(p) ItemPointerSet((p), InvalidBlockNumber, (OffsetNumber)0xffff)
#define ItemPointerIsMax(p) \
    (GinItemPointerGetOffsetNumber(p) == (OffsetNumber)0xffff && GinItemPointerGetBlockNumber(p) == InvalidBlockNumber)
#define ItemPointerSetLossyPage(p, b) ItemPointerSet((p), (b), (OffsetNumber)0xffff)
#define ItemPointerIsLossyPage(p) \
    (GinItemPointerGetOffsetNumber(p) == (OffsetNumber)0xffff && GinItemPointerGetBlockNumber(p) != InvalidBlockNumber)

/*
 * Posting item in a non-leaf posting-tree page
 */
typedef struct {
    /* We use BlockIdData not BlockNumber to avoid padding space wastage */
    BlockIdData child_blkno;
    ItemPointerData key;
} PostingItem;

#define PostingItemGetBlockNumber(pointer) BlockIdGetBlockNumber(&(pointer)->child_blkno)

#define PostingItemSetBlockNumber(pointer, blockNumber) BlockIdSet(&((pointer)->child_blkno), (blockNumber))

/*
 * Category codes to distinguish placeholder nulls from ordinary NULL keys.
 * Note that the datatype size and the first two code values are chosen to be
 * compatible with the usual usage of bool isNull flags.
 *
 * GIN_CAT_EMPTY_QUERY is never stored in the index; and notice that it is
 * chosen to sort before not after regular key values.
 */
typedef signed char GinNullCategory;

#define GIN_CAT_NORM_KEY 0       /* normal, non-null key value */
#define GIN_CAT_NULL_KEY 1       /* null key value */
#define GIN_CAT_EMPTY_ITEM 2     /* placeholder for zero-key item */
#define GIN_CAT_NULL_ITEM 3      /* placeholder for null item */
#define GIN_CAT_EMPTY_QUERY (-1) /* placeholder for full-scan query */

/*
 * Access macros for null category byte in entry tuples
 */
#define GinCategoryOffset(itup, ginstate) \
    (IndexInfoFindDataOffset((itup)->t_info) + ((ginstate)->oneCol ? 0 : sizeof(int16)))
#define GinGetNullCategory(itup, ginstate) (*((GinNullCategory *)((char *)(itup) + GinCategoryOffset(itup, ginstate))))
#define GinSetNullCategory(itup, ginstate, c) \
    (*((GinNullCategory *)((char *)(itup) + GinCategoryOffset(itup, ginstate))) = (c))

/*
 * Access macros for leaf-page entry tuples (see discussion in README)
 */
#define GinGetNPosting(itup) GinItemPointerGetOffsetNumber(&(itup)->t_tid)
#define GinSetNPosting(itup, n) ItemPointerSetOffsetNumber(&(itup)->t_tid, n)
#define GIN_TREE_POSTING ((OffsetNumber)0xffff)
#define GinIsPostingTree(itup) (GinGetNPosting(itup) == GIN_TREE_POSTING)
#define GinSetPostingTree(itup, blkno) do { \
    GinSetNPosting((itup), GIN_TREE_POSTING);         \
    ItemPointerSetBlockNumber(&(itup)->t_tid, blkno); \
} while (0)

#define GinGetPostingTree(itup) GinItemPointerGetBlockNumber(&(itup)->t_tid)

#define GIN_ITUP_COMPRESSED ((uint32)1 << 31)
#define GinGetPostingOffset(itup) (GinItemPointerGetBlockNumber(&(itup)->t_tid) & (~GIN_ITUP_COMPRESSED))
#define GinSetPostingOffset(itup, n) ItemPointerSetBlockNumber(&(itup)->t_tid, (n) | GIN_ITUP_COMPRESSED)
#define GinGetPosting(itup) ((Pointer)((char *)(itup) + GinGetPostingOffset(itup)))
#define GinItupIsCompressed(itup) (GinItemPointerGetBlockNumber(&(itup)->t_tid) & GIN_ITUP_COMPRESSED)

/*
 * Maximum size of an item on entry tree page. Make sure that we fit at least
 * three items on each page. (On regular B-tree indexes, we must fit at least
 * three items: two data items and the "high key". In GIN entry tree, we don't
 * currently store the high key explicitly, we just use the rightmost item on
 * the page, so it would actually be enough to fit two items.)
 */
#define GinMaxItemSize                                                                                      \
    Min(INDEX_SIZE_MASK, MAXALIGN_DOWN(((BLCKSZ - MAXALIGN(SizeOfPageHeaderData + 3 * sizeof(ItemIdData)) - \
                                         MAXALIGN(sizeof(GinPageOpaqueData))) /                             \
                                        3)))

/*
 * Access macros for non-leaf entry tuples
 */
#define GinGetDownlink(itup) GinItemPointerGetBlockNumber(&(itup)->t_tid)
#define GinSetDownlink(itup, blkno) ItemPointerSet(&(itup)->t_tid, blkno, InvalidOffsetNumber)

/*
 * Data (posting tree) pages
 *
 * Posting tree pages don't store regular tuples. Non-leaf pages contain
 * PostingItems, which are pairs of ItemPointers and child block numbers.
 * Leaf pages contain GinPostingLists and an uncompressed array of item
 * pointers.
 *
 * In a leaf page, the compressed posting lists are stored after the regular
 * page header, one after each other. Although we don't store regular tuples,
 * pd_lower is used to indicate the end of the posting lists. After that, free
 * space follows.  This layout is compatible with the "standard" heap and
 * index page layout described in bufpage.h, so that we can e.g set buffer_std
 * when writing WAL records.
 *
 * In the special space is the GinPageOpaque struct.
 */
#define GinDataLeafPageGetPostingList(page) \
    (GinPostingList *)((PageGetContents(page) + MAXALIGN(sizeof(ItemPointerData))))
#define GinDataLeafPageGetPostingListSize(page) \
    (((PageHeader)page)->pd_lower - MAXALIGN(SizeOfPageHeaderData) - MAXALIGN(sizeof(ItemPointerData)))

#define GinDataLeafPageIsEmpty(page)                                            \
    (GinPageIsCompressed(page) ? (GinDataLeafPageGetPostingListSize(page) == 0) \
                                : (GinPageGetOpaque(page)->maxoff < FirstOffsetNumber))

#define GinDataLeafPageGetFreeSpace(page) PageGetExactFreeSpace(page)

#define GinDataPageGetRightBound(page) ((ItemPointer)PageGetContents(page))
/*
 * Pointer to the data portion of a posting tree page. For internal pages,
 * that's the beginning of the array of PostingItems. For compressed leaf
 * pages, the first compressed posting list. For uncompressed (pre-9.4) leaf
 * pages, it's the beginning of the ItemPointer array.
 */
#define GinDataPageGetData(page) (PageGetContents(page) + MAXALIGN(sizeof(ItemPointerData)))
/* non-leaf pages contain PostingItems */
#define GinDataPageGetPostingItem(page, i) ((PostingItem *)(GinDataPageGetData(page) + ((i)-1) * sizeof(PostingItem)))

/*
 * Note: there is no GinDataPageGetDataSize macro, because before version
 * 9.4, we didn't set pd_lower on data pages. There can be pages in the index
 * that were binary-upgraded from earlier versions and still have an invalid
 * pd_lower, so we cannot trust it in general. Compressed posting tree leaf
 * pages are new in 9.4, however, so we can trust them; see
 * GinDataLeafPageGetPostingListSize.
 */
#define GinDataPageSetDataSize(page, size) do { \
    Assert((uintptr_t)size <= GinDataPageMaxDataSize);                                                          \
    ((PageHeader)page)->pd_lower = (size) + MAXALIGN(SizeOfPageHeaderData) + MAXALIGN(sizeof(ItemPointerData)); \
} while (0)

#define GinNonLeafDataPageGetFreeSpace(page) \
    (GinDataPageMaxDataSize - GinPageGetOpaque(page)->maxoff * sizeof(PostingItem))

#define GinDataPageMaxDataSize \
    (BLCKSZ - MAXALIGN(SizeOfPageHeaderData) - MAXALIGN(sizeof(ItemPointerData)) - MAXALIGN(sizeof(GinPageOpaqueData)))

/*
 * List pages
 */
#define GinListPageSize (BLCKSZ - SizeOfPageHeaderData - MAXALIGN(sizeof(GinPageOpaqueData)))

/*
 * Storage type for GIN's reloptions
 */
typedef struct GinOptions {
    int32 vl_len_;              /* varlena header (do not touch directly!) */
    bool useFastUpdate;         /* use fast updates? */
    int pendingListCleanupSize; /* maximum size of pending list */
} GinOptions;

#define GIN_DEFAULT_USE_FASTUPDATE true
#define GinGetUseFastUpdate(relation) \
    ((relation)->rd_options ? ((GinOptions *)(relation)->rd_options)->useFastUpdate : GIN_DEFAULT_USE_FASTUPDATE)
#define GinGetPendingListCleanupSize(relation)                                                      \
    ((relation)->rd_options && ((GinOptions *)(relation)->rd_options)->pendingListCleanupSize != -1 \
            ? ((GinOptions *)(relation)->rd_options)->pendingListCleanupSize                           \
            : u_sess->attr.attr_storage.gin_pending_list_limit)

/* Macros for buffer lock/unlock operations */
#define GIN_UNLOCK BUFFER_LOCK_UNLOCK
#define GIN_SHARE BUFFER_LOCK_SHARE
#define GIN_EXCLUSIVE BUFFER_LOCK_EXCLUSIVE

/*
 * GinState: working data structure describing the index being worked on
 */
typedef struct GinState {
    Relation index;
    bool oneCol; /* true if single-column index */

    /*
     * origTupDesc is the nominal tuple descriptor of the index, ie, the i'th
     * attribute shows the key type (not the input data type!) of the i'th
     * index column.  In a single-column index this describes the actual leaf
     * index tuples.  In a multi-column index, the actual leaf tuples contain
     * a smallint column number followed by a key datum of the appropriate
     * type for that column.  We set up tupdesc[i] to describe the actual
     * rowtype of the index tuples for the i'th column, ie, (int2, keytype).
     * Note that in any case, leaf tuples contain more data than is known to
     * the TupleDesc; see access/gin/README for details.
     */
    TupleDesc origTupdesc;
    TupleDesc tupdesc[INDEX_MAX_KEYS];

    /*
     * Per-index-column opclass support functions
     */
    FmgrInfo compareFn[INDEX_MAX_KEYS];
    FmgrInfo extractValueFn[INDEX_MAX_KEYS];
    FmgrInfo extractQueryFn[INDEX_MAX_KEYS];
    FmgrInfo consistentFn[INDEX_MAX_KEYS];
    FmgrInfo triConsistentFn[INDEX_MAX_KEYS];
    FmgrInfo comparePartialFn[INDEX_MAX_KEYS]; /* optional method */
    /* canPartialMatch[i] is true if comparePartialFn[i] is valid */
    bool canPartialMatch[INDEX_MAX_KEYS];
    /* Collations to pass to the support functions */
    Oid supportCollation[INDEX_MAX_KEYS];
} GinState;

typedef enum {
    ROW_STORE_TYPE = 0,
    COL_STORE_TYPE = 1,
} GinPostingListType;

/*
 * A compressed posting list.
 *
 * Note: This requires 2-byte alignment.
 */
typedef struct {
    GinPostingListType type;                    /* posting list type for row or column cstore */
    ItemPointerData first;                      /* first item in this posting list (unpacked) */
    uint16 nbytes;                              /* number of bytes that follow */
    unsigned char bytes[FLEXIBLE_ARRAY_MEMBER]; /* varbyte encoded items (variable length) */
} GinPostingList;

#define SizeOfGinPostingList(plist) (offsetof(GinPostingList, bytes) + SHORTALIGN((plist)->nbytes))
#define GinNextPostingListSegment(cur) ((GinPostingList *)(((char *)(cur)) + SizeOfGinPostingList((cur))))

/* XLog stuff */
#define XLOG_GIN_CREATE_INDEX 0x00
#define XLOG_GIN_CREATE_PTREE 0x10

typedef struct ginxlogCreatePostingTree {
    uint32 size;
    /* A compressed posting list follows */
} ginxlogCreatePostingTree;

/*
 * The format of the insertion record varies depending on the page type.
 * ginxlogInsert is the common part between all variants.
 *
 * Backup Blk 0: target page
 * Backup Blk 1: left child, if this insertion finishes an incomplete split
 */
#define XLOG_GIN_INSERT 0x20

typedef struct {
    uint16 flags; /* GIN_INSERT_ISLEAF and/or GIN_INSERT_ISDATA */

    /*
     * FOLLOWS:
     *
     * 1. if not leaf page, block numbers of the left and right child pages
     * whose split this insertion finishes, as BlockIdData[2] (beware of
     * adding fields in this struct that would make them not 16-bit aligned)
     *
     * 2. a ginxlogInsertEntry or ginxlogRecompressDataLeaf struct, depending
     * on tree type.
     *
     * NB: the below structs are only 16-bit aligned when appended to a
     * ginxlogInsert struct! Beware of adding fields to them that require
     * stricter alignment.
     */
} ginxlogInsert;

typedef struct ginxlogInsertEntry {
    OffsetNumber offset;
    bool isDelete;
    IndexTupleData tuple; /* variable length */
} ginxlogInsertEntry;

typedef struct {
    uint16 nactions;

    /* Variable number of 'actions' follow */
} ginxlogRecompressDataLeaf;

/*
 * Note: this struct is currently not used in code, and only acts as
 * documentation. The WAL record format is as specified here, but the code
 * uses straight access through a Pointer and memcpy to read/write these.
 */
typedef struct {
    uint8 segno; /* segment this action applies to */
    char type;   /* action type (see below) */

    /*
     * Action-specific data follows. For INSERT and REPLACE actions that is a
     * GinPostingList struct. For ADDITEMS, a uint16 for the number of items
     * added, followed by the items themselves as ItemPointers. DELETE actions
     * have no further data.
     */
} ginxlogSegmentAction;

/* Action types */
#define GIN_SEGMENT_UNMODIFIED 0 /* no action (not used in WAL records) */
#define GIN_SEGMENT_DELETE 1     /* a whole segment is removed */
#define GIN_SEGMENT_INSERT 2     /* a whole segment is added */
#define GIN_SEGMENT_REPLACE 3    /* a segment is replaced */
#define GIN_SEGMENT_ADDITEMS 4   /* items are added to existing segment */

typedef struct ginxlogInsertDataInternal {
    OffsetNumber offset;
    PostingItem newitem;
} ginxlogInsertDataInternal;

/*
 * Backup Blk 0: new left page (= original page, if not root split)
 * Backup Blk 1: new right page
 * Backup Blk 2: original page / new root page, if root split
 * Backup Blk 3: left child, if this insertion completes an earlier split
 */
#define XLOG_GIN_SPLIT 0x30

typedef struct ginxlogSplit {
    RelFileNode node;
    BlockNumber rrlink;         /* right link, or root's blocknumber if root
                                 * split */
    BlockNumber leftChildBlkno; /* valid on a non-leaf split */
    BlockNumber rightChildBlkno;
    uint16 flags; /* see below */
} ginxlogSplit;

/*
 * Flags used in ginxlogInsert and ginxlogSplit records
 */
#define GIN_INSERT_ISDATA 0x01 /* for both insert and split records */
#define GIN_INSERT_ISLEAF 0x02 /* ditto */
#define GIN_SPLIT_ROOT 0x04    /* only for split records */

typedef struct {
    OffsetNumber separator;
    OffsetNumber nitem;

    /* FOLLOWS: IndexTuples */
} ginxlogSplitEntry;

typedef struct {
    uint16 lsize;
    uint16 rsize;
    ItemPointerData lrightbound; /* new right bound of left page */
    ItemPointerData rrightbound; /* new right bound of right page */

    /* FOLLOWS: new compressed posting lists of left and right page */
    char newdata[1];
} ginxlogSplitDataLeaf;

typedef struct {
    OffsetNumber separator;
    OffsetNumber nitem;
    ItemPointerData rightbound;

    /* FOLLOWS: array of PostingItems */
} ginxlogSplitDataInternal;

/*
 * Vacuum simply WAL-logs the whole page, when anything is modified. This
 * is functionally identical to heap_newpage records, but is kept separate for
 * debugging purposes. (When inspecting the WAL stream, it's easier to see
 * what's going on when GIN vacuum records are marked as such, not as heap
 * records.) This is currently only used for entry tree leaf pages.
 */
#define XLOG_GIN_VACUUM_PAGE 0x40

/*
 * Vacuuming posting tree leaf page is WAL-logged like recompression caused
 * by insertion.
 */
#define XLOG_GIN_VACUUM_DATA_LEAF_PAGE 0x90

typedef struct ginxlogVacuumDataLeafPage {
    ginxlogRecompressDataLeaf data;
} ginxlogVacuumDataLeafPage;

/*
 * Backup Blk 0: deleted page
 * Backup Blk 1: parent
 * Backup Blk 2: left sibling
 */
#define XLOG_GIN_DELETE_PAGE 0x50

typedef struct ginxlogDeletePage {
    OffsetNumber parentOffset;
    BlockNumber rightLink;
} ginxlogDeletePage;

#define XLOG_GIN_UPDATE_META_PAGE 0x60

/*
 * Backup Blk 0: metapage
 * Backup Blk 1: tail page
 */
typedef struct ginxlogUpdateMeta {
    RelFileNode node;
    GinMetaPageData metadata;
    BlockNumber prevTail;
    BlockNumber newRightlink;
    int32 ntuples; /* if ntuples > 0 then metadata.tail was
                    * updated with that many tuples; else new sub
                    * list was inserted */
                   /* array of inserted tuples follows */
} ginxlogUpdateMeta;

#define XLOG_GIN_INSERT_LISTPAGE 0x70

typedef struct ginxlogInsertListPage {
    BlockNumber rightlink;
    int32 ntuples;
    /* array of inserted tuples follows */
} ginxlogInsertListPage;
/*
 * Backup Blk 0: metapage
 * Backup Blk 1 to (ndeleted + 1): deleted pages
 */
#define XLOG_GIN_DELETE_LISTPAGE 0x80

/*
 * The WAL record for deleting list pages must contain a block reference to
 * all the deleted pages, so the number of pages that can be deleted in one
 * record is limited by XLR_MAX_BLOCK_ID. (block_id 0 is used for the
 * metapage.)
 */
#define GIN_NDELETE_AT_ONCE Min(16, XLR_MAX_BLOCK_ID - 1)
typedef struct ginxlogDeleteListPages {
    GinMetaPageData metadata;
    int32 ndeleted;
} ginxlogDeleteListPages;

/* ginutil.c */
extern Datum ginoptions(PG_FUNCTION_ARGS);
extern void initGinState(GinState *state, Relation index);
extern Buffer GinNewBuffer(Relation index);
extern void GinInitBuffer(Buffer b, uint32 f);
extern void GinInitPage(Page page, uint32 f, Size pageSize);
extern void GinInitMetabuffer(Buffer b);
extern void GinInitMetaPage(Page page, Size pageSize);
extern int ginCompareEntries(GinState *ginstate, OffsetNumber attnum, Datum a, GinNullCategory categorya, Datum b,
                             GinNullCategory categoryb);
extern int ginCompareAttEntries(GinState *ginstate, OffsetNumber attnuma, Datum a, GinNullCategory categorya,
                                OffsetNumber attnumb, Datum b, GinNullCategory categoryb);
extern Datum *ginExtractEntries(GinState *ginstate, OffsetNumber attnum, Datum value, bool isNull, int32 *nentries,
                                GinNullCategory **categories);

extern OffsetNumber gintuple_get_attrnum(GinState *ginstate, IndexTuple tuple);
extern Datum gintuple_get_key(GinState *ginstate, IndexTuple tuple, GinNullCategory *category);

/* gininsert.c */
extern Datum ginmerge(PG_FUNCTION_ARGS);
extern Datum ginbuild(PG_FUNCTION_ARGS);
extern Datum ginbuildempty(PG_FUNCTION_ARGS);
extern Datum gininsert(PG_FUNCTION_ARGS);
extern void ginEntryInsert(GinState *ginstate, OffsetNumber attnum, Datum key, GinNullCategory category,
                           ItemPointerData *items, uint32 nitem, GinStatsData *buildStats);
extern Datum cginbuild(PG_FUNCTION_ARGS);

/* ginbtree.c */
typedef struct GinBtreeStack {
    BlockNumber blkno;
    Buffer buffer;
    OffsetNumber off;
    ItemPointerData iptr;
    /* predictNumber contains predicted number of pages on current level */
    uint32 predictNumber;
    struct GinBtreeStack *parent;
} GinBtreeStack;

typedef struct GinBtreeData *GinBtree;

/* Return codes for GinBtreeData.beginPlaceToPage method */
typedef enum {
    GPTP_NO_WORK,
    GPTP_INSERT,
    GPTP_SPLIT
} GinPlaceToPageRC;

typedef struct GinBtreeData {
    /* search methods */
    BlockNumber (*findChildPage)(GinBtree, GinBtreeStack *);
    BlockNumber (*getLeftMostChild)(GinBtree, Page);
    bool (*isMoveRight)(GinBtree, Page);
    bool (*findItem)(GinBtree, GinBtreeStack *);

    /* insert methods */
    OffsetNumber (*findChildPtr)(GinBtree, Page, BlockNumber, OffsetNumber);
    GinPlaceToPageRC (*beginPlaceToPage)(GinBtree, Buffer, GinBtreeStack *, void *, BlockNumber, void **, Page *,
                                         Page *);
    void (*execPlaceToPage)(GinBtree, Buffer, GinBtreeStack *, void *, BlockNumber, void *);
    void *(*prepareDownlink)(GinBtree, Buffer);
    void (*fillRoot)(GinBtree, Page, BlockNumber, Page, BlockNumber, Page);

    bool isData;

    Relation index;
    BlockNumber rootBlkno;
    GinState *ginstate; /* not valid in a data scan */
    bool fullScan;
    bool isBuild;

    /* Search key for Entry tree */
    OffsetNumber entryAttnum;
    Datum entryKey;
    GinNullCategory entryCategory;

    /* Search key for data tree (posting tree) */
    ItemPointerData itemptr;
} GinBtreeData;

/* This represents a tuple to be inserted to entry tree. */
typedef struct {
    IndexTuple entry; /* tuple to insert */
    bool isDelete;    /* delete old tuple at same offset? */
} GinBtreeEntryInsertData;

/*
 * This represents an itempointer, or many itempointers, to be inserted to
 * a data (posting tree) leaf page
 */
typedef struct {
    ItemPointerData *items;
    uint32 nitem;
    uint32 curitem;
} GinBtreeDataLeafInsertData;

/*
 * For internal data (posting tree) pages, the insertion payload is a
 * PostingItem
 */
extern GinBtreeStack *ginFindLeafPage(GinBtree btree, bool searchMode);
extern Buffer ginStepRight(Buffer buffer, Relation index, int lockmode);
extern void freeGinBtreeStack(GinBtreeStack *stack);
extern void ginInsertValue(GinBtree btree, GinBtreeStack *stack, void *insertdata, GinStatsData *buildStats);

/* ginentrypage.c */
extern IndexTuple GinFormTuple(GinState *ginstate, OffsetNumber attnum, Datum key, GinNullCategory category,
                               Pointer data, Size dataSize, int nipd, bool errorTooBig);
extern void ginPrepareEntryScan(GinBtree btree, OffsetNumber attnum, Datum key, GinNullCategory category,
                                GinState *ginstate);
extern void ginEntryFillRoot(GinBtree btree, Page root, BlockNumber lblkno, Page lpage, BlockNumber rblkno, Page rpage);
extern ItemPointer ginReadTuple(GinState *ginstate, OffsetNumber attnum, IndexTuple itup, int *nitems);

/* gindatapage.c */
extern ItemPointer GinDataLeafPageGetItems(Page page, int *nitems, ItemPointerData advancePast);
extern int GinDataLeafPageGetItemsToTbm(Page page, TIDBitmap *tbm);
extern BlockNumber createPostingTree(Relation index, ItemPointerData *items, uint32 nitems, GinStatsData *buildStats);
extern void GinDataPageAddPostingItem(Page page, PostingItem *data, OffsetNumber offset);
extern void GinPageDeletePostingItem(Page page, OffsetNumber offset);
extern void ginInsertItemPointers(Relation index, BlockNumber rootBlkno, ItemPointerData *items, uint32 nitem,
                                  GinStatsData *buildStats);
extern GinBtreeStack *ginScanBeginPostingTree(GinBtree btree, Relation index, BlockNumber rootBlkno);
extern void ginDataFillRoot(GinBtree btree, Page root, BlockNumber lblkno, Page lpage, BlockNumber rblkno, Page rpage);
extern void ginPrepareDataScan(GinBtree btree, Relation index, BlockNumber rootBlkno);

/*
 * This is declared in ginvacuum.c, but is passed between ginVacuumItemPointers
 * and ginVacuumPostingTreeLeaf and as an opaque struct, so we need a forward
 * declaration for it.
 */
typedef struct GinVacuumState GinVacuumState;

extern void ginVacuumPostingTreeLeaf(Relation rel, Buffer buf, GinVacuumState *gvs);

/* ginscan.c */
/*
 * GinScanKeyData describes a single GIN index qualifier expression.
 *
 * From each qual expression, we extract one or more specific index search
 * conditions, which are represented by GinScanEntryData.  It's quite
 * possible for identical search conditions to be requested by more than
 * one qual expression, in which case we merge such conditions to have just
 * one unique GinScanEntry --- this is particularly important for efficiency
 * when dealing with full-index-scan entries.  So there can be multiple
 * GinScanKeyData.scanEntry pointers to the same GinScanEntryData.
 *
 * In each GinScanKeyData, nentries is the true number of entries, while
 * nuserentries is the number that extractQueryFn returned (which is what
 * we report to consistentFn).  The "user" entries must come first.
 */
typedef struct GinScanKeyData *GinScanKey;

typedef struct GinScanEntryData *GinScanEntry;

typedef struct GinScanKeyData {
    /* Real number of entries in scanEntry[] (always > 0) */
    uint32 nentries;
    /* Number of entries that extractQueryFn and consistentFn know about */
    uint32 nuserentries;

    /* array of GinScanEntry pointers, one per extracted search condition */
    GinScanEntry *scanEntry;

    /*
     * At least one of the entries in requiredEntries must be present for a
     * tuple to match the overall qual.
     *
     * additionalEntries contains entries that are needed by the consistent
     * function to decide if an item matches, but are not sufficient to
     * satisfy the qual without entries from requiredEntries.
     */
    GinScanEntry *requiredEntries;
    int nrequired;
    GinScanEntry *additionalEntries;
    int nadditional;

    /* array of check flags, reported to consistentFn */
    GinTernaryValue *entryRes;
    bool (*boolConsistentFn)(GinScanKey key);
    GinTernaryValue (*triConsistentFn)(GinScanKey key);
    FmgrInfo *consistentFmgrInfo;
    FmgrInfo *triConsistentFmgrInfo;
    Oid collation;

    /* other data needed for calling consistentFn */
    Datum query;
    /* NB: these three arrays have only nuserentries elements! */
    Datum *queryValues;
    GinNullCategory *queryCategories;
    Pointer *extra_data;
    StrategyNumber strategy;
    int32 searchMode;
    OffsetNumber attnum;

    /*
     * Match status data.  curItem is the TID most recently tested (could be a
     * lossy-page pointer).  curItemMatches is TRUE if it passes the
     * consistentFn test; if so, recheckCurItem is the recheck flag.
     * isFinished means that all the input entry streams are finished, so this
     * key cannot succeed for any later TIDs.
     */
    ItemPointerData curItem;
    bool curItemMatches;
    bool recheckCurItem;
    bool isFinished;
} GinScanKeyData;

typedef struct GinScanEntryData {
    /* query key and other information from extractQueryFn */
    Datum queryKey;
    GinNullCategory queryCategory;
    bool isPartialMatch;
    Pointer extra_data;
    StrategyNumber strategy;
    int32 searchMode;
    OffsetNumber attnum;

    /* Current page in posting tree */
    Buffer buffer;

    /* current ItemPointer to heap */
    ItemPointerData curItem;

    /* for a partial-match or full-scan query, we accumulate all TIDs here */
    TIDBitmap *matchBitmap;
    TBMIterator *matchIterator;
    TBMIterateResult *matchResult;

    ItemPointerData *matchList;
    int matchNum;

    /* used for Posting list and one page in Posting tree */
    ItemPointerData *list;
    int nlist;
    int offset;

    bool isFinished;
    bool reduceResult;
    uint32 predictNumberResult;
    GinBtreeData btree;
} GinScanEntryData;

typedef struct GinScanOpaqueData {
    MemoryContext tempCtx;
    GinState ginstate;

    GinScanKey keys; /* one per scan qualifier expr */
    uint32 nkeys;

    GinScanEntry *entries; /* one per index search condition */
    uint32 totalentries;
    uint32 allocentries; /* allocated length of entries[] */

    MemoryContext keyCtx; /* used to hold key and entry data */

    bool isVoidRes; /* true if query is unsatisfiable */
} GinScanOpaqueData;

typedef GinScanOpaqueData *GinScanOpaque;

extern Datum ginbeginscan(PG_FUNCTION_ARGS);
extern Datum ginendscan(PG_FUNCTION_ARGS);
extern Datum ginrescan(PG_FUNCTION_ARGS);
extern Datum ginmarkpos(PG_FUNCTION_ARGS);
extern Datum ginrestrpos(PG_FUNCTION_ARGS);
extern void ginNewScanKey(IndexScanDesc scan);
extern void ginFreeScanKeys(GinScanOpaque so);

/* ginget.c */
extern Datum gingetbitmap(PG_FUNCTION_ARGS);
extern Datum cgingetbitmap(PG_FUNCTION_ARGS);

/* ginfast.c */
extern Datum gin_clean_pending_list(PG_FUNCTION_ARGS);

/* ginlogic.c */
extern void ginInitConsistentFunction(GinState *ginstate, GinScanKey key);

/* ginvacuum.c */
extern Datum ginbulkdelete(PG_FUNCTION_ARGS);
extern Datum ginvacuumcleanup(PG_FUNCTION_ARGS);
extern ItemPointer ginVacuumItemPointers(GinVacuumState *gvs, ItemPointerData *items, int nitem, int *nremaining);

/* ginbulk.c */
typedef struct GinEntryAccumulator {
    RBNode rbnode;
    Datum key;
    GinNullCategory category;
    OffsetNumber attnum;
    bool shouldSort;
    ItemPointerData *list;
    uint32 maxcount; /* allocated size of list[] */
    uint32 count;    /* current number of list[] entries */
} GinEntryAccumulator;

typedef struct {
    GinState *ginstate;
    Size allocatedMemory;
    GinEntryAccumulator *entryallocator;
    uint32 eas_used;
    RBTree *tree;
} BuildAccumulator;

extern void ginInitBA(BuildAccumulator *accum);
extern void ginInsertBAEntries(BuildAccumulator *accum, ItemPointer heapptr, OffsetNumber attnum, Datum *entries,
                               GinNullCategory *categories, int32 nentries);
extern void ginBeginBAScan(BuildAccumulator *accum);
extern ItemPointerData *ginGetBAEntry(BuildAccumulator *accum, OffsetNumber *attnum, Datum *key,
                                      GinNullCategory *category, uint32 *n);

/* ginfast.c */
typedef struct GinTupleCollector {
    IndexTuple *tuples;
    uint32 ntuples;
    uint32 lentuples;
    uint32 sumsize;
} GinTupleCollector;

extern void ginHeapTupleFastInsert(GinState *ginstate, GinTupleCollector *collector);
extern void ginHeapTupleFastCollect(GinState *ginstate, GinTupleCollector *collector, OffsetNumber attnum, Datum value,
                                    bool isNull, ItemPointer ht_ctid);
extern void ginInsertCleanup(GinState* ginstate, bool full_clean, bool fill_fsm, bool forceCleanup,
                             IndexBulkDeleteResult* stats);

/* ginpostinglist.c */
extern GinPostingList *ginCompressPostingList(const ItemPointer ptrs, int nptrs, int maxsize, int *nwritten,
                                              bool isColStore);
extern int ginPostingListDecodeAllSegmentsToTbm(GinPostingList *ptr, int totalsize, TIDBitmap *tbm);

extern ItemPointer ginPostingListDecodeAllSegments(GinPostingList *ptr, int len, int *ndecoded);
extern ItemPointer ginPostingListDecode(GinPostingList *ptr, int *ndecoded);
extern ItemPointer ginMergeItemPointers(ItemPointerData *a, uint32 na, ItemPointerData *b, uint32 nb, int *nmerged);
extern void GinRedoRecompress(Page page, ginxlogRecompressDataLeaf* data);
/*
 * Merging the results of several gin scans compares item pointers a lot,
 * so we want this to be inlined. But if the compiler doesn't support that,
 * fall back on the non-inline version from itemptr.c. See STATIC_IF_INLINE in
 * c.h.
 */
static inline int ginCompareItemPointers(ItemPointer a, ItemPointer b)
{
    uint64 ia = ((uint64)a->ip_blkid.bi_hi << 32) | ((uint64)a->ip_blkid.bi_lo << 16) | a->ip_posid;
    uint64 ib = ((uint64)b->ip_blkid.bi_hi << 32) | ((uint64)b->ip_blkid.bi_lo << 16) | b->ip_posid;

    if (ia == ib)
        return 0;
    else if (ia > ib)
        return 1;
    else
        return -1;
}

#endif /* GIN_PRIVATE_H */
